RU2417735C1 - Method of iris identification of personality (versions) - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: group of inventions refers to object access security and can be used for iris diagnosis of status of organs and functional systems. Iris colour image is recorded and processed to generate an identification code elements of which are determined according to wave length or a set of wave lengths of reflected light and its intensity from each iris element. The fact of identification of personality is established by a preset match degree of the generated identification code and the stored one generated earlier. In the other version of the invention, the iris image is recorded in several spectral ranges and processed in the same several various spectral ranges to generate the identification code by wave length or a set of wave lengths of reflected light and its intensity from each iris element. The fact of identification of personality is established by a preset match degree of the generated identification code and the stored one generated earlier.

EFFECT: group of the inventions allows higher accuracy and rate of identification.

12 cl, 7 ex

Description

The invention relates to techniques for protecting various objects from access by unauthorized persons by identifying a person by the image of her iris (HORN) and can be used to diagnose the state of organs and functional systems of the body by HORN.

A known method of identifying a person by the image of her iris, which provides for the registration of HORN images of people and the formation on their basis of a database, which is then used to identify the person. Each image before being placed in the database is processed in a computer using special software and stored as a specific data set. To carry out the process of identifying a person, an image of her HORN is recorded, the captured image is processed and compared with those stored in the database (WO 03/049010 [1]).

A disadvantage of the known method of identifying a person is its relatively low accuracy, since a single set of characteristic features is used to identify a person, i.e. one code.

A known method of identifying a person by the image of her iris, which provides for the registration of HORN images of people and the formation on their basis of a database, which is then used to identify the person. At the same time, in the process of registering an Horn image, the eye is illuminated by optical radiation in a narrow spectral range. Semiconductor radiation sources are used as a source of such illumination. Each image before being placed in the database is processed in a computer using special software and stored as a specific code. To carry out the process of identifying a person, an image of her HORN is recorded, the captured image is processed and compared with those stored in the database (JP 10137220 [2]).

A disadvantage of the known method of identifying a person is its relatively low accuracy, since a single set of characteristic features is used to identify a person, i.e. one code.

A known method of identifying a person’s identity by its Horn, which is as follows: it was found that the use of backlight in one spectral range due to differences in the color of the pigment of Horn in some cases does not allow to accurately determine the boundary between the protein and the iris, and, moreover, some of the characteristic features of the HOG are not detected due to poor contrast when using backlight, the wavelength of which is close to the color of these elements. Therefore, in the known method, the eyes of an identifiable person are first illuminated with light close to infrared, the color of the pigment of the Horn is detected, and depending on this, the wavelength of the optical radiation source used to illuminate the Horn is selected at the time of recording its image. As a result of image processing, a code corresponding to it is generated, which is stored in the database and used for comparison with the current code value generated by re-registering the HOR image of an identifiable person (JP 2006031185 [3]).

A disadvantage of the known method of identifying a person, despite the fact that the resulting codes carry information about a greater number of characteristic elements, is its relatively low accuracy, since a single set of characteristic features is used to identify a person, i.e. one code.

Closest to the claimed are methods of identifying a person by the iris of the eye (ROG), known from RU 2326589 [4]. One of the methods involves registering a color image of the HOG and its subsequent processing in several different spectral (color) ranges and the formation of an identification code for each of them, while the fact of identification is established by the coincidence of identification codes in all processed spectral ranges. The second method involves registering the HOG image in several spectral (color) ranges and its subsequent processing in the same several different spectral ranges and generating an identification code for each of them, while the fact of identification is established by the coincidence of identification codes in several or all spectral ranges .

A disadvantage of the known methods of identifying a person is that despite the fact that the resulting codes carry information about a greater number of characteristic elements, they also carry redundant information, since they are obtained from one statistically independent space, which increases the total length of the code and, as a result, increases the search time in the database.

The inventive methods for identifying a person by the iris (HOR) are aimed at improving the accuracy and speed of identification.

This result is achieved by the fact that the method of identifying a person by the Horn includes recording a color image of the Horn and its subsequent processing with the formation of an identification code, the elements of which are determined in accordance with the calculated wavelength or the set of wavelengths of the reflected light radiation and its intensity from each element of the Horn, this fact, the identification of the person is established by a given degree of coincidence of the generated identification code with the stored and generated earlier.

The indicated result is also achieved by the fact that in the process of registering the HOGs are illuminated with optical radiation, the spectral range of which is close to white light.

The indicated result is also achieved by the fact that the illuminating radiation is concentrated in the focus region of the recording system.

The indicated result is also achieved by the fact that the illuminating radiation is concentrated on the resulting image as much as possible inside the pupil girdle.

The indicated result is also achieved by the fact that the illuminating radiation is modulated in intensity.

The indicated result is also achieved by the fact that in the process of processing the HOG, when forming the identification code, the physiological features of the Horn (autonomous ring, lacunae, age spots, etc.) are separately taken into account.

This result is achieved by the fact that the method of identifying a person by HORN includes registering an HORN image in several spectral ranges and its subsequent processing in the same several different spectral ranges and the formation of an identification code, the elements of which are determined in accordance with the calculated wavelength or the set of wavelengths of the reflected light radiation and its intensity from each element of the Horn, while the fact of identification is established by a given degree of coincidence was formed with the identification code previously generated and stored.

The indicated result is also achieved by the fact that during the registration of the HOG in each of the spectral ranges it is highlighted with optical radiation, the spectral range of which corresponds to the spectral range of registration.

The indicated result is also achieved by the fact that the illuminating radiation is concentrated in the focus region of the recording system.

The indicated result is also achieved by the fact that the illuminating radiation is concentrated on the resulting image as much as possible inside the pupil girdle.

The indicated result is also achieved by the fact that the illuminating radiation, at least in one of the spectral ranges, is modulated in intensity.

The indicated result is also achieved by the fact that in the process of processing the HOG, when forming the identification code, the physiological features of the Horn (autonomous ring, lacunae, age spots, etc.) are separately taken into account.

Registration of the color image of the Horn and its subsequent processing with the formation of an identification code, the elements of which are determined in accordance with the calculated wavelength or the set of wavelengths of the reflected light radiation and its intensity from each element of the Horn, allows you to use, previously not used or not used correctly, color the information component contained in the registered image of the Horn.

The use of optical radiation illumination, the spectral range of which is close to white light, in the process of registering HOGs increases the accuracy of identification, since, on the one hand, it allows one to obtain a color image of Horns with virtually no distortion in the spectral characteristics of its elements, and, on the other hand, to select a sufficiently large number of spectra (or spectral lines, or spectral ranges) in which this image can be processed.

It is most advisable to concentrate the illumination radiation in the focus area of the recording system, since in this case it will be most rational to use the backlight system with its energy consumption tending to a minimum. This also increases the accuracy of identification, since it can be used as a system of visual positioning of the HOG in the system registration area.

It is also possible to increase the accuracy of personal identification due to the fact that the highlighting radiation is concentrated on the received image as much as possible inside the pupil girdle, since this allows you to get a HOR image with minimal light interference artifacts on the useful area of the received HOR image.

In addition, if the illuminating radiation is modulated in intensity, it can be determined whether the identifiable person is using contact lenses and / or if the eye, the Horn image of which is subjected to analysis, does not belong to a living person, but to a fake or corpse.

Separate accounting for the identification of the physiological features of the HOG during the formation of an identification code (autonomous ring, gaps, age spots, etc.) increases the accuracy and increases the identification speed, since it provides the identification code with an additional unique characteristic.

The second proposed method of identifying a person, like the first one, allows to increase the accuracy of identification of a person and is based on a principle similar to him, namely, it provides for registering an HOR image in several spectral ranges and its subsequent processing in the same several different spectral ranges and formation identification code, the elements of which are determined in accordance with the calculated wavelength or a set of wavelengths of the reflected light radiation and its intensity from each of the second element of the HORN, which allows the use of various types of combined illuminators and the most accurate color correction.

In order to further improve the accuracy of personal identification, it is advisable to illuminate it with optical radiation in each of the spectral ranges during the registration of the HOG, the spectral range of which corresponds to the spectral range of registration. In this case, an increase in accuracy is achieved by the specific spectral components identified by the highlighting features that are characteristic of different types of irises (hazel, gray or mixed type).

As in the first method, it is advisable to concentrate the illuminating radiation in the focus area of the recording system, since in this case it will be most rational to use the backlight system with its energy consumption tending to a minimum. This also increases the accuracy of identification, since it can be used as a system of visual positioning of the HOG in the system registration area.

It is also possible to increase the accuracy of personal identification due to the fact that the highlighting radiation is concentrated on the received image as much as possible inside the pupil girdle, since this allows you to get a HOR image with minimal light interference artifacts on the useful area of the received HOR image.

If in the first method the entire flux of illuminating radiation is modulated in intensity, since it is the only one, then in this method, taking into account that several HOR images are recorded sequentially in different spectral ranges and the illumination is performed by optical radiation of different ranges, it is possible to modulate the radiation of only one spectral range or it is possible to modulate a combination of several different emission ranges. The main thing is that the reaction of the pupil girdle to a modulated change in the intensity of radiation from the backlight of the iris is most maximum and effective.

Separate accounting for the identification of the physiological features of the HOG during the formation of an identification code (autonomous ring, gaps, age spots, etc.) increases the accuracy and increases the identification speed, since it provides the identification code with an additional unique characteristic.

The essence of the proposed methods is illustrated by examples of their implementation.

Example 1. In the most general case, the first method described in claim 1 of the claims is carried out as follows. The identifiable person is placed in the field of view of the registration tools, allowing to obtain a high-quality color image of the Horn. As such a means, a color television video camera with a digital output can be used or a digital camera that allows you to take pictures at small intervals of about 0.05 s. The resulting image is converted to digital form and transmitted to a personal computer equipped with appropriate software (see WO 03/053123 [5]). In accordance with the image processing program, the computer generates a code from the registered color image, which is stored in the database as a reference. Subsequently, when there is a problem of identification of a person with the purpose of permitting his access or passage, for example, to a protected area, some storehouse, when crossing state borders, the procedure described above is repeated, except that the code obtained from this identification it is compared with those already stored in the database, and if the codes of the identified person coincide (with a given degree), access or passage is allowed.

Example 2. In the particular case of the first method can be carried out as follows. The identifiable person is placed in the field of view of the registration tools, allowing to obtain a high-quality color image of the Horn. As such a means, a color camera with a digital output can be used, or a digital camera allowing photographs to be taken at small intervals of the order of 0.05 s, while in the process of registering an HOR image, it is illuminated with optical radiation whose spectral range is close to white light. For this purpose, known radiation sources can be used, for example superbright LEDs of a certain luminance range or other sources. Since it is optimal to perform illumination in such a way that the radiation is concentrated on the one hand in the focus area of the recording system, and on the other hand, on the resulting image of the HRO maximally inside the pupil girdle, the backlight should be installed as close as possible to the area captured by the registration, but if possible Do not fall into it. The resulting image is converted to digital form and transmitted to a personal computer equipped with the appropriate software (see for example [4] or - PrivatelD® from Iridian Technologies is an image processing protocol and data standard that enables a Proof Positive-certified iris camera to capture an image, process it and prepare it for transport in the most secure way possible. Iris recognition is the most accurate, non-invasive and easy to use biometric for secure identification. http://www.iriscan.com/products.php?page = 1).

In accordance with the image processing program, a computer from the registered color image forms a few monochrome and highlights the characteristics of each analyzed image. Based on the isolation and analysis of the HOG images, a code is generated that is stored in the database as a reference. Subsequently, when there is a problem of identification of a person with the purpose of permitting his access or passage, for example, to a protected area, some storehouse, when crossing state borders, the procedure described above is repeated, except that the code obtained from this identification it is compared with those already stored in the database and if the codes of the identified person coincide (with a given degree), access or passage is allowed.

Example 3. In another particular case, ensuring maximum achievement of the result, the first method can be implemented as follows. The identifiable person is placed in the field of view of the registration tools, allowing to obtain a high-quality color image of the Horn. As such a means, a color camera with a digital output can be used, or a digital camera allowing photographs to be taken at small intervals of the order of 0.05 s, while in the process of registering an HOR image, it is illuminated with optical radiation, the spectral range of which is close to white light. For this purpose, known radiation sources can be used, for example superbright LEDs of a certain luminance range or other sources. Since it is optimal to perform illumination in such a way that the radiation is concentrated on the one hand in the focus area of the recording system, and on the other hand, on the resulting image as much as possible inside the pupil girdle, the backlight should be installed as close as possible to the area captured by the registration. The resulting image is converted to digital form and transmitted to a personal computer equipped with appropriate software. (http://www.iriscan.com/products.php?page=1).

In accordance with the image processing program, the computer generates a code from the registered color image, which is stored in the database as a reference. Subsequently, when there is a problem of identification of a person with the purpose of permitting his access or passage, for example, to a protected area, some storehouse, when crossing state borders, the procedure described above is repeated, except that the code obtained from this identification it is compared with those already stored in the database, while the initial search in the database is carried out according to the physiological characteristics of the HOGs that were previously stored separately, and if the identity codes (with the necessary degree) coincide, it can be access or passage allowed. But before giving such permission, you need to make sure that the image of the Horn is obtained from the eye of a living person, and not from his dummy. To do this, the illuminating radiation is modulated in intensity, and the image registration system monitors the pupil's response to modulation, for which the recording time is slightly increased.

Example 4. In one embodiment, the first method was carried out as follows. An identifiable person was placed in the field of view of a color television video camera (for example, Sanyo VCC-6592P) with an analog output, which, through the conversion unit, converts the signal to a digital output, which was connected to the input of a personal computer. In the process of registering the HOR image, it was illuminated with optical radiation with a spectral range close to white light. For this, the so-called sources of super-bright radiation were used (for example, Al171 v3). The radiation sources were placed as close as possible to the region captured by the registration, so that they did not fall into it and so that the radiation was concentrated, on the one hand, in the focus area of the recording system, and on the other hand, on the resulting image as much as possible inside the pupil girdle. The resulting image was converted by the conversion unit into digital form and transmitted to a personal computer equipped with software that allows to extract the necessary spectral components involved in the identification from the received information. As a result of processing the registered color image, the computer generated an identification code, the elements of which were determined in accordance with the calculated wavelength or the set of wavelengths of the reflected light radiation and its intensity from each element of the HOG. Further, the identification code was stored in the database as a reference. To verify the functioning of the method, the identifiable person was secondarily subjected to the above procedure. After completing the procedure, the resulting code was compared with that stored in the database. As a result, the codes were obtained (with the necessary degree), which means that an identified person can be allowed access or passage, for example, to a protected area. But before giving such permission, you need to make sure that the image of the Horn is obtained from the eye of a living person, and not from his dummy. To verify the effectiveness of the method, a color photograph of the HORN of an identifiable person with certain properties close to the living eye was made. Since it is necessary to modulate the illumination radiation in intensity to verify the Horn for reliability, two experiments were performed when, in one case, an identifiable person was placed in the field of view, and in the other case, a dummy of his eyes. In the process of recording both images, both the eyes and the dummy were highlighted by intensity-modulated radiation with a variable frequency, which was selected from the conditions of the reaction of the pupil to a given frequency of exposure. In this case, it was ~ 1.5 Hz and was carried out over a time period of no more than 2 s. For this, the value of the supply current supplied to superbright LEDs was changed. The image continuously recorded by the television camera was transferred to a computer, the image processing program of which allows recording the change in the diameter of the pupil. As a result, when the image of a living person was recorded, a signal confirming this fact was displayed on the computer monitor. When a dummy was placed in the field of view of a television camera, the computer revealed this fact and issued a prohibitory signal to enter the protected area.

Example 5. In the most general case, the second method described in claim 7 of the claims is carried out as follows. The identifiable person is placed in the field of view of the registration tools, allowing to obtain a high-quality color image of the Horn. As such a means, a color camera with a digital output can be used or a digital camera can be used to take pictures at small intervals of about 0.05 s. The eye of an identifiable person is placed in the field of view of the registration means and its HORN is sequentially recorded in a certain color - red, green, blue, etc. The resulting images, converted to digital form, are transmitted to a personal computer equipped with appropriate software. Based on the analysis of monochrome ROG images, a code is generated (the wavelength or the set of wavelengths of the reflected light radiation and its intensity for each element of the ROG are calculated by computer processing the set of received images), which is stored in the database as a reference. Subsequently, when there is a problem of identification of a person with the purpose of permitting his access or passage, for example, to a protected area, some storehouse, when crossing state borders, the procedure described above is repeated, except that the code obtained from this identification it is compared with those already stored in the database and if the codes of the identified person coincide (with the necessary degree), access or passage is allowed.

Example 6. In the particular case of the second method can be carried out as follows. An identifiable person is placed in the field of view of the registration means, which allows to obtain a high-quality image of the Horn in the required spectra. As such means, a combination of cameras with digital outputs and appropriate filters can be used. The eye registration means of the identifiable person placed in the field of view is highlighted by optical radiation with different wavelengths that could correspond to certain spectra - red, yellow, green, blue, IR, etc. Accordingly, using the registration tool and a computer connected to it, several HOR images are recorded, each of which was highlighted at the time of recording a certain spectrum of optical radiation. The resulting images, converted to digital form, are transmitted to a personal computer equipped with appropriate software. Based on the analysis of monochrome ROG images (the formation of an identification code according to the calculated wavelength or the set of wavelengths of the reflected light radiation and its intensity from each element of the ROG through computer processing of the set of received images), a code is generated that is stored in the database as a reference. To illuminate the eye at the time of fixing its monochrome images, known radiation sources, for example various LEDs or radiation sources with appropriate filters, can be used.

Since it is optimal to perform illumination in such a way that the radiation is concentrated on the one hand in the focus area of the recording system, and on the other hand, on the resulting image as much as possible inside the pupil girdle, the backlight should be installed as close as possible to the area captured by the registration, but if possible, so that they do not fall into it.

Subsequently, when there is a problem of identification of a person with the purpose of permitting his access or passage, for example, to a protected area, some storehouse, when crossing state borders, the procedure described above is repeated, except that the code obtained from this identification it is compared with those already stored in the database and if the codes of the identified person coincide (with the necessary degree), access or passage is allowed.

Example 7. In another particular case, ensuring maximum achievement of the result, the second method can be implemented as follows. The identifiable person is placed in the field of view of the registration means, allowing to obtain a high-quality image of the Horn. As such a means, a camera with a digital output and appropriate filters can be used. The eye identification means of the identifiable person placed in the field of view is highlighted by optical radiation with different wavelengths that can correspond to certain spectra or colors - red, yellow, green, blue, etc. Accordingly, using the registration tool and a computer connected to it, several HOR images are recorded, each of which was highlighted at the time of recording a certain spectrum of optical radiation. The resulting images, converted to digital form, are transmitted to a personal computer equipped with appropriate software. Based on the analysis and calculation of the wavelength or the set of wavelengths of the reflected light radiation and its intensity, a code is generated from each element of the HOG, which is stored in the database as a reference.

To illuminate the eye at the time of fixing its monochrome images, known radiation sources, for example various LEDs or radiation sources with appropriate filters, can be used.

Since it is optimal to illuminate in such a way that the radiation is concentrated, on the one hand, in the focus area of the recording system, and on the other hand, on the resulting image as much as possible inside the pupil girdle, the backlight should be installed as close as possible to the area captured by the registration.

Subsequently, when there is a problem of identification of a person with the purpose of permitting his access or passage, for example, to a protected area, some storehouse, when crossing state borders, the procedure described above is repeated, except that the code obtained from this identification it is compared with those already stored in the database, while the primary search in the database is carried out according to separately stored physiological characteristics of the HOG, and if the identity codes (with the necessary degree) coincide, it can be resolved access or passage. But before giving such permission, you need to make sure that the image of the Horn is obtained from the eye of a living person, and not from his dummy. To do this, the illuminating radiation, at least in one of the spectral ranges (color), is modulated in intensity, and the image registration system monitors the pupil's response to modulation, for which the recording time is slightly increased.

Example 8. In one embodiment, the second method was carried out as follows. An identifiable person was placed in the field of view of a color television video camera with a digital output after signal conversion, which was connected to the input of a personal computer. The eye identification means of the identifiable person placed in the field of view was sequentially illuminated by optical radiation with different wavelengths that corresponded to specific colors - red, green, blue. Accordingly, with the help of the registration tool and the computer connected to it, these three HOR images were recorded, each of which was highlighted at the time of registration by optical radiation of the color in which the registration was carried out. To this end, radiation sources were used (super-bright LEDs for the red spectrum of the backlight - BSOL445-1HGB, for the blue spectrum - BB445 - 1F and for the green spectrum of the backlight - BGD1445 - 1L5). The radiation sources were placed around the circle as close as possible to the region captured by the registration, so that they did not fall into it and so that the radiation of all the illumination sources was concentrated on the one hand in the focus area of the recording system, and on the other hand, the resulting image was maximally inside the pupil belt. The resulting image was converted by the video camera itself into digital form and transmitted to a personal computer equipped with software that allows the computer to analyze several received monochrome images and calculate the wavelength or the set of wavelengths of the reflected light radiation and its intensity from each element of the ROG.

As a result of processing three monochrome images - red, blue and green images of the HOG, a code was generated that was saved in the database as a reference. To verify the functioning of the method, the identifiable person was secondarily subjected to the above procedure. After completing the procedure, the resulting code was compared with those stored in the database. As a result, the necessary coincidence of codes was obtained, which means that an identified person can be allowed access or passage, for example, to a protected area.

But before giving such permission, you need to make sure that the image of the Horn is obtained from the eye of a living person, and not from his dummy. To verify the effectiveness of the method, a color photograph of the HORN of an identifiable person with certain properties close to the living eye was made. To test the reaction of the pupil, the illuminating radiation must be modulated in intensity. Two experiments were conducted when, in one case, an identifiable personality was placed in the field of view, and in the other case, a fake of his eyes. In the process of recording both images, both the eyes and the dummy were highlighted by intensity-modulated radiation of simultaneously blue and green. To do this, we changed the value of the supply current supplied to the LEDs of the corresponding color (for the blue spectrum - BB445 - 1F and for the green spectrum of the backlight - BGD1445 - 1L5).

The image continuously recorded by the television camera was transferred to a computer, the image processing program of which allows recording the change in the diameter of the pupil. As a result, when the image of a living person was recorded, a signal confirming this fact was displayed on the computer monitor. When a dummy was placed in the field of view of a television camera, the computer revealed this fact and issued a prohibitory signal to enter the protected area.

Claims (12)

1. A method of identifying a person by the iris (HOR), including recording a color image of the HOG and its subsequent processing with the formation of an identification code, the elements of which are determined in accordance with the wavelength or the set of wavelengths of the reflected light radiation and its intensity from each element of the HOG, at the same time, the fact of personal identification is established according to a given degree of coincidence of the generated identification code with the stored one generated earlier. 2. The method according to claim 1, characterized in that in the process of registering the HOGs are illuminated with optical radiation, the spectral range of which is close to white light. 3. The method according to claim 2, characterized in that the illuminating radiation is concentrated in the focus area of the recording system. 4. The method according to claim 2, characterized in that the illuminating radiation is concentrated on the resulting image as much as possible inside the pupil girdle. 5. The method according to claim 2, characterized in that the illuminating radiation is modulated in intensity. 6. The method according to claim 1, characterized in that in the process of processing the HOG when forming the identification code, the physiological features of the Horn are taken into account. 7. A method of identifying a person by an HORN, including registering an HOR image in several spectral ranges and its subsequent processing in the same several different spectral ranges with the formation of an identification code, the elements of which are determined in accordance with the wavelength or the set of wavelengths of the reflected light radiation and its intensity from each element of the HORN, while the fact of identification is established by a given degree of coincidence of the generated identification code with previously formed. 8. The method according to claim 7, characterized in that during the registration of the HOG in each of the spectral ranges it is highlighted with optical radiation, the spectral range of which corresponds to the spectral range of registration. 9. The method according to claim 8, characterized in that the illuminating radiation is concentrated in the focus area of the recording system. 10. The method according to claim 8, characterized in that the illuminating radiation is concentrated on the resulting image as much as possible inside the pupil girdle. 11. The method according to claim 8, characterized in that the illuminating radiation, at least in one of the spectral ranges, is modulated in intensity. 12. The method according to claim 7, characterized in that in the process of processing the HORN while forming the identification code, the physiological characteristics of the HORN are separately taken into account.